Bifidobacterium bifidum DS0908 and Bifidobacterium longum DS0950 Culture-Supernatants Ameliorate Obesity-Related Characteristics in Mice with High-Fat Diet-Induced Obesity

Probiotic supplements have promising therapeutic effects on chronic diseases. In this study, we demonstrated the anti-obesity effects of two potential probiotics, Bifidobacterium bifidum DS0908 (DS0908) and Bifidobacterium longum DS0950 (DS0950). Treatment with DS0908 and DS0950 postbiotics significantly induced the expression of the brown adipocyte-specific markers UCP1, PPARγ, PGC1α, PRDM16 and beige adipocyte-specific markers CD137, FGF21, P2RX5, and COX2 in C3H10T1/2 mesenchymal stem cells (MSCs). In mice with high-fat diet (HFD)-induced obesity, both potential probiotics and postbiotics noticeably reduced body weight and epididymal fat accumulation without affecting food intake. DS0908 and DS0950 also improved insulin sensitivity and glucose use in mice with HFD-induced obesity. In addition, DS0908 and DS0950 improved the plasma lipid profile, proved by reduced triglyceride, low-density lipoprotein, and cholesterol levels. Furthermore, DS0908 and DS0950 improved mitochondrial respiratory function, confirmed by the high expression of oxidative phosphorylation proteins, during thermogenesis induction in the visceral and epididymal fat in mice with HFD-induced obesity. Notably, the physiological and metabolic changes were more significant after treatment with potential probiotic culture-supernatants than those with the bacterial pellet. Finally, gene knockdown and co-treatment with inhibitor-mediated mechanistic analyses showed that both DS0908 and DS0950 exerted anti-obesity-related effects via the PKA/p38 MAPK signaling activation in C3H10T1/2 MSCs. Our observations suggest that DS0908 and DS0950 could potentially alleviate obesity as dietary supplements.


Introduction
Probiotics are a group of beneficial gut microorganisms that reportedly alleviate several chronic diseases, such as obesity, cancer, cardiovascular disease, and type 2 diabetes [1,2]. They are commonly found in infant gut microbiomes and improve an infant's immunity [2]. They colonize the gastrointestinal tract and catabolize human milk oligosaccharides, a common source of prebiotics (i.e., non-digestible food components that complement probiotic growth) for their growth [3]. They produce several postbiotics (i.e., short-, medium-and long-chain fatty acids) and secondary metabolites [4]. Probiotics reportedly interact directly with human intestinal epithelial cells, enhancing anti-inflammatory responses [4,5]. Furthermore, postbiotics (e.g., short-chain fatty acids) reportedly improve energy metabolism and adiposity [6][7][8]. One of the striking features of postbiotics is the ability to penetrate the blood-brain barrier and regulate sustainable energy homeostasis by improving insulin or leptin receptor signaling, achieved via G-coupled protein receptor (GPR) signaling modulation [9,10]. Recent studies show that sustainable energy metabolism improvement is an attractive therapeutic approach for obesity and comorbidities [11][12][13][14].
Obesity is characterized by the imbalance of energy preservation and expenditure in metabolic systems, mainly those of the body fat cells; white, brown and the newly discovered beige (or brite) adipocytes. The relatively lipidladen white adipocytes contain fewer mitochondria and contribute to obesity by hypertrophy, lipid content increase, or hyperplasia. Adipokines secreted by white adipocytes cause normal metabolic dysfunction and several metabolic diseases [15][16][17]. In contrast, brown adipocytes ameliorate obesity by inducing energy expenditure. They activate mitochondrial oxidative phosphorylation and uncoupling protein 1 (UCP1), a mitochondrial inner membrane protein [16]. Brown adipocytes exhibit multi-locular lipid droplets potentially generated during lipolysis in the mitochondrial fat β-oxidation process, as reported in multiple studies [18,19]. Also, the newly discovered beige adipocytes share features similar to the brown adipocytes commonly found in white-fat deposits. Beige adipocytes originate both from white adipocytes (undergoing a process called browning) and adipogenic progenitors [18][19][20][21][22]. Therefore, discovery of potential therapeutic candidates to induce brown or beige adipocyte activity has emerged as a popular obesity treatment option.
Recent studies have shown that probiotics exhibit significant potential to mitigate obesity. Certain strains of a common probiotic species, Bifidobacterium, are widely used as dietary supplements and functional foods, and reportedly improve metabolic function and protect against dysmetabolic diseases. For example, Bifidobacterium infantis, one of the most abundant gut microbes in breastfeeding infants, displays the ability to improve infant immunity, including the induction of protective antibody production, and directly affects adipocyte physiology [12,30,31]. A lower count of Bifidobacterium species in the gut microbiome increases the risk of childhood obesity [12]. B. infantis catabolizes human milk oligosaccharides, improving UCP1 and leading to abundant multi-locular lipid droplet levels in adipocytes [12]. We have previously demonstrated that B. infantis reduces lipid accumulation and induces browning in white adipocytes [7,8]. In this study, we describe how B. bifidum DS0908 and B. longum DS0950 can induce thermogenesis under both in vitro and in vivo conditions, and may have significant therapeutic potential against obesity.

Bacteria Isolation and Identification
Two Bifidobacterium strains, B. bifidum DS0908 and B. longum DS0950, were isolated from 1 g of human fecal sample diluted in 10 ml of sterilized 0.85% PBS solution. Serially diluted fecal supernatants were spread on De Man, Rogosa and Sharpe (MRS) agar medium (Becton, Dickinson and Company, USA) and incubated in an anaerobic chamber (Coy Laboratory Products, USA) filled with 5% H 2 , 10% CO 2 and 85% N 2 at 37°C. After 48 h, a single ivory colony was obtained and identified by 16S rRNA sequencing. For 16S rRNA sequencing, the bacterial genomic DNA was extracted as described previously [32]. The 16S rRNA gene sequence was amplified using the universal primers 27F (5-AGAGTTTGATCMTGGCTCAG-3) and 1492R (5-TACGGYTACCTTGTTACGACTT-3). To ascertain the phylogenetic position of the isolates, we compared the 16S rRNA gene sequences with sequences obtained from the EzBioCloud (https://www.ezbiocloud.net/) and GenBank/EMBL/DDBJ (http:// www.ncbi.nlm.nih.gov/blast) databases, respectively. The bacterial strains were deposited in the Korean Collection for Type Cultures (KCTC 13935BP for B. bifidum DS0908 and KCTC 13936BP for B. longum DS0950).

Probiotic Culture-Supernatant Preparation
Bacterial cells were cultured on MRS agar at 37°C in an anaerobic chamber. After 48 h, a single colony was picked, seeded onto 30 ml of fresh MRS medium and grown for 36 h at 37°C under anaerobic conditions. The liquid medium was purged with ultra-pure nitrogen gas for 15 min before autoclaving to achieve anaerobic conditions. The residual oxygen was removed by keeping the medium air-permeable in an anaerobic chamber. The oxygen concentration was controlled to 0 ppm when measured with a CAM-12 anaerobic monitor (Coy Laboratory Products). Culture supernatants were collected after centrifugation of the microbial culture (CFU; 5 × 10 9 cells/ml) at 11,000 ×g for 20 min, then freeze-dried and dissolved in 1/10 th volume of distilled water (v/v). The culture supernatants were stored at −20°C until further use. B. bifidum DS0908 and B. longum DS0950 culture supernatants (postbiotics and secondary metabolites) were selected using qRT-PCR based Ucp1-screening assay as described previously [8]. According to J. Prasad et al., our studied bacterial strains adhere to the requirements of potential probiotics [33]. The probiotic bacterial strains used in the screening assay are listed in Table S1.

Cell Culture
C3H10T1/2 MSCs (KCLB-10226; passage number ≥ 10) were cultured in DMEM GlutaMax supplemented with 10% FBS and 1% penicillin-streptomycin solution in a humidified 5% CO 2 incubator at 37°C. For adipogenic differentiation, sufficiently confluent C3H10T1/2 MSCs (2 days post confluence, designated as day 0) were incubated with an adipogenic differentiation cocktail MDI (0.5 mM IBMX, 1 μM dexamethasone and 10 μg/ml insulin), with or without DS0908 and DS0950 in DMEM supplemented with 10% FBS. Treatments exceeding two days were continued until day 4, and DS0908 and DS0950 were added to the maturation medium containing DMEM, insulin and 10% FBS for cell culture on days 3 and 4. After day 4, only the maturation medium was used until harvest. Fully differentiated C3H10T1/2 MSCs were harvested on day 6 and used for the study. Incubation in MDI served as a negative control, and incubation with Rosi (1 μM) in DMEM was a positive control.

Animal Studies
Specific-pathogen-free (SPF) male C57BL/6 mice (6 weeks old) were purchased from Koatech (Korea) and maintained at 22°C ± 2°C under 40-60% relative humidity and a 12:12 h, light-dark cycle for one week to stabilize their metabolism. The mice were fed a normal-fat diet (NFD, D12450B, Research Diets Inc., USA) or a high-fat diet (HFD) (D12492, Research Diets Inc.) for four weeks to generate mice with HFD-induced obesity before DS0908 or DS0950 administration. Then, the mice were separated into seven groups of 8 individuals (n = 8) as follows: G1 (NFD), G2 (HFD), G3 (HFD + BS [culture supernatants of DS0908]), G4 (HFD + BS [culture supernatants of DS0950]), G5 (HFD + bacterial pellet (BP) of DS0908]), G6 (HFD + BP [bacterial pellet of DS0950]) and G7 (HFD + Rosi). The mice were administered DS0908 or DS0950 pellets (1 × 10 9 cells/kg) or culture supernatants (150 ml/mouse) by oral gavage for five days a week for eight weeks. Body weight and food intake were recorded once and three times a week. After six weeks of administration, we randomly selected 4 mice from each group and mice were fasted for 16 h and 5 h for oral glucose tolerance test (OGTT) and insulin tolerance test (ITT), respectively. Before injection, we collected blood as a baseline control (0 min). After glucose (OGTT) or insulin (ITT) injection, we measured blood glucose levels at 15, 30, 60, 90, and 120 min. The liver, as well as subcutaneous, epididymal, and mesenteric fat were then surgically removed, weighed, immediately frozen in liquid nitrogen, and immersed in RNAlater (Thermo Fisher Scientific), or fixed in 10% neutral formalin. The animal use and care protocol for this experiment was approved by the Institutional Animal Care and Use Committee at Korea Research Institute of Bioscience and Biotechnology (KRIBB) (approval no. KRIBB-AEC-20093).

Haematoxylin and Eosin (H&E) Staining
The tissues (epididymal fat and liver) were fixed in 4% paraformaldehyde, embedded in paraffin, and cut into 10-μm sections. Standard H&E staining was performed using standard protocols. Five random fields of each section were evaluated, and the average adipocyte diameter was measured using the ImageJ software (NIH, USA).

Quantitative RT-PCR Analysis
We harvested C3H10T1/2 MSCs and extracted total RNA using an RNA Extraction Kit (Qiagen, USA) following the manufacturer's guidelines. We used 1 μg RNA to synthesize cDNA using the Maxime RT PreMix Kit (Intron Biotechnology, Korea) on a Veriti 96-Well Thermal Cycler (Applied Biosystems, Singapore). qRT-PCR was performed using an iQ SYBR Green Supermix Kit (Bio-Rad, Singapore) on a CFX96 Real-Time PCR Detection System (Bio-Rad). Tbp was an internal control. Table 1 contains the sequence information of the primers.

Western Blot Analysis
Differentiated and treated C3H10T1/2 MSCs were prepared in RIPA lysis buffer supplemented with protease inhibitors. The total protein concentration was measured using the BCA Protein Assay Kit (Thermo Fisher   Table 1. Primers used in this study. GGCTGAAGGCAAAGTCAGTGT TGGAATCTGTCCTGCTGTCCT mTbp GAAGCTGCGGTACAATTCCAG CCCCTTGTACCCTTCACCAAT Scientific). Equal amounts of protein samples were separated on a 4-20% sodium dodecyl sulfate-polyacrylamide gradient gel (Mini-PROTEAN Precast Gel, Bio-Rad) and transferred onto polyvinylidene difluoride (PVDF) membranes. The PVDF membranes were then blocked and incubated with specific antibodies, as indicated in the figures. Immunoreactive protein bands were captured using the chemiluminescent ECL (Advansta Inc., USA) assay on ChemiDoc XRS + with ImageLab (Bio-Rad). Anti-β-actin antibody was used as a loading control for each protein expression. Protein band intensities were quantified using the ImageJ software.

Statistical Analysis
All values are expressed as the average ± standard error mean (SEM). The experimental determinants were confirmed by using at least triplicate biological samples. Student's t-test or two-way ANOVA (OGTT, ITT, body weight gain, and food intake) were used to distinguish the statistical significance levels, where *, **, ***, and ns indicates p < 0.05, < 0.01 and < 0.001, and no significance, respectively.

Treatment with DS0908 and DS0950 Reduces Weight Gain and Fat Accumulation without Altering Food Intake in Mice with HFD-Induced Obesity
The thermogenic and lipid-lowering potential of DS0908 and DS0950 culture supernatants prompted us to examine how they could potentially affect HFD-induced obesity in mice. To evaluate the DS0908 and DS0950 administration effect on mice with HFD-induced C57BL/6 obesity, we randomly assigned eight C57BL/6 mice (n = 8) into seven groups as follows: NFD; (G1), HFD; (G2), HFD + BS (cell-free supernatant) of DS0908 (G3), HFD

Fig. 2. DS0908 and DS0950 supplementation reduce bodyweight and fat accumulation without altering food intake in mice with HFD-induced obesity. (A) Illustration of the dietary intervention timeline of mice with high-fat diet
(HFD)-induced obesity and treatment group designs (n = 8 mice/per group). (B) Change in body weight growth curve with the average of whole-body weight gain after seven weeks in DS0908-and DS0950-administered mice with HFD-induced obesity compared to control mice group (NFD). (C) Haematoxylin and eosin (H&E) staining images of epididymal adipose tissue and lipid droplet area quantification among tissues from different mouse groups. The data are expressed as the average ± standard error mean (SEM). *, **, *** and ns indicate p < 0.05, < 0.01, < 0.001 and non-significant, respectively, to express the statistically significant differences between the control (G2: HFD) and treatment groups. G1: Normal-fat diet (NFD); G2: High-fat diet (HFD); G3: BS DS0908 (DS0908); G4: BS DS0950 (DS0950); G5: BP DS0908 (DS0908; 10 9 cells/kg); G6: BP DS0950 (DS0950; 10 9 cells/kg); G7: Rosiglitazone (Rosi; 10 mg/kg); BS = bacterial supernatant; BP = bacterial pellets. + BS (cell-free supernatant) of DS0950 (G4), HFD + BP (bacterial pellets) of DS0908 (G5), HFD + BP (bacterial pellets) of DS0950 (G6), and HFD + Rosiglitazone (G7). The HFD groups were fed a 45% HFD for four weeks to induce obesity in the animals ( Fig. 2A). The mice with HFD-induced obesity were then administered DS0908 or DS0950 culture supernatants or pellets. In DS0908-and DS0950-administered obese mice, food intake and body weight were monitored for up to seven weeks. We observed no significant change in food intake in DS0908-and DS0950-administered (both cell-free probiotic supernatants and pellets) obese mice compared to the control HFD group (Fig. S2A). However, the overall weight gain in DS0908-and DS0950-supplemented obese mice was not distinguishable from that in the HFD-fed group after seven weeks. The HFD group gained significant body weight compared to the NFD group throughout the seven weeks (Fig. 2B). In contrast, DS0908 and DS0950 supplementation (with both BP and BS) in C57BL/6 obese mice resulted in a significant body weight gain reduction throughout the seven weeks (Fig. 2B). In addition, we evaluated the effect of DS0908 and DS0950 culture supernatants and bacterial pellets of epididymal adipocyte size after H&E staining. We observed that the HFD group showed a larger adipocyte size than the NFD and Rosi (positive control) groups (Fig. 2C). Interestingly, adipocyte size in the case of the known thermogenesis-inducer rosiglitazone was similar to that in the NFD group. However, DS0908 and DS0950 supplementation (both with BP and BS) in HFD-induced C57BL/6 obese mice markedly reduced adipocyte size compared to that in the HFD-fed group. Adipocyte size in the DS0950 culture supernatant-supplemented group was smaller than that in the HFD group and similar to that in the Rosiadministered group (Fig. 2C). Next, we measured the common lipid-accumulated fat depot weights. DS0908 and DS0950 supplementation (both with BP and BS) slightly reduced epididymal, visceral, and subcutaneous fat, as well as liver weight compared to the HFD group (Fig. S2B). Interestingly, these fat depot weights were significantly reduced in the Rosi-administered group compared to those in the HFD-fed group (Fig. S2B). These results indicated that the administration of both DS0908 and DS0950 effectively alleviated HFD-induced obesity by lowering body weight and adipocyte hypertrophy without affecting food intake in mice with HFD-induced obesity.

Treatment with DS0908 and DS0950 Improves Insulin Sensitivity, Glucose Mmetabolism, and Lipid Profile in Mice with HFD-Induced Obesity
To evaluate how DS0908 and DS0950 culture supernatants and bacterial pellets affect glucose metabolism and plasma lipid profiles, ITT and OGTT were performed after forty-four days of treatment. DS0908 and DS0950 supplementation (with BP and BS) noticeably reduced insulin levels, suggesting improved insulin sensitivity

Treatment with DS0908 and DS0950 Improves Thermogenesis via PKA/p38 MAPK Signaling in C3H10T1/2 MSCs
To understand the underlying mechanism of DS0908 and DS0950 culture supernatants related to thermogenesis, we examined the PKA, CREB, p38 MAPK and AMPK signaling pathways (Fig. S3A). First, we measured PKA and p38 MAPK phosphorylation after the DS0908 and DS0950 treatments. Both PKA and p38 MAPK phosphorylation markedly increased 60 min after the DS0908 and DS0950 treatments compared to MDI. However, the DS0908 and DS0950 treatments reduced AMPK and CREB S133 phosphorylation (Fig. 4A). These after incubation with DS0908 and DS0950 for 10, 30, and 60 min. The confluent C3H10T1/2 MSCs were serum-depleted for 8 h, incubated with DS0908 and DS0950 for the indicated periods, then the phosphorylated proteins were detected. (B) Phosphorylation levels of PKA and p38 MAPK after treatment with 8-br-cAMP (PKA activator), H89 (pan-PKA inhibitor) and SB 203580 (p38 MAPK inhibitor) with or without DS0908 and DS0950. (C) mRNA expression levels of p38 MAPKα in Pkaα and p38 MAPKα-knockdown cells, and their downstream thermogenic genes Ucp1, Pgc1α, Prdm16 and Pparγ after silencing of Pkaα and p38 MAPKα and treatment with DS0908 and DS0950 (siPkaα/sip38 MAPKα + DS0908 or DS0950 group) and control siRNA and treatment with DS0908 or DS0950 (siCont + DS0908 or DS0950 group). (D) Protein expression levels (UCP1, PGC1α, PRDM16 and PPARγ) were measured after silencing of Pkaα and p38 MAPKα and treatment with DS0908 or DS0950 (siPkaα/sip38 MAPKα + DS0908 or DS0950 group) and control siRNA and treatment with DS0950 or DS0908 (siCont + DS0908 or DS0950 group). The gene knockdown experiments were designed as siCont vs. siCont + DS0908 or DS0950, siPkaα vs. siPkaα + DS0908 or DS0950 and sip38 MAPKα vs. sip38 MAPKα + DS0908 or DS0950. Post silencing with the siRNA, C3H10T1/2 mesenchymal stem cells (MSCs) were differentiated as described in Methods. Tbp was used as an internal control gene and β-actin as a protein loading control. The data from three individual experiments are expressed as the average ± standard error mean (SEM). *, **, *** and ns indicate p < 0.05, < 0.01, < 0.001 and non-significant, respectively, to express the statistically significant differences between the control (MDI) and the treatment groups in the figures. The protein band intensities were measured using ImageJ. Adipogenic differentiation medium, MDI: 0.5 mM IBMX, 1 μM dexamethasone and 10 μg/ml insulin; 1 μM Rosiglitazone (Rosi); DS0908 = B. bifidum DS0908; DS0950 = B. longum DS0950. findings suggest that DS0908 and DS0950 culture supernatants might induce thermogenesis via PKA and p38 MAPK signaling in C3H10T1/2 MSCs. To confirm these findings, we performed a competitive chemical inhibition assay, co-treating DS0908 and DS0950 culture supernatants with H89 (a pan-PKA inhibitor) and SB 203580 (a p38 MAPK inhibitor). We observed that PKA and p38 MAPK phosphorylation decreased after the H89 and SB 203580 treatments, respectively. However, co-treatment with DS0908 and DS0950 culture supernatants recovered PKA and p38 MAPK phosphorylation. Notably, the p38 MAPK expression recovery was higher in DS0908 and DS0950 culture supernatant-related C3H10T1/2 MSCs (Fig. 4B). Under DS0908 and DS0950 culture supernatant co-treatment conditions, the H89 treatment reduced p38 MAPK expression. In contrast, PKA expression remained unaffected after the SB 203580 treatment, suggesting that PKA might be upstream of p38 MAPK. Furthermore, we performed PKAα or p38 MAPKα knockdown using small interfering RNA (siRNA) (Figs. 4C, 4D, and S3B). In PKAα-silenced cells, p38 MAPKα mRNA expression decreased by ~20%, whereas the DS0908 and DS0950 culture supernatant treatments markedly recovered the p38 MAPKα mRNA expression (1.82-and 2.11-fold). In contrast, the p38 MAPKα-silenced cells reduced the p38 MAPKα mRNA expression bỹ 50%, although the DS0908 and DS0950 culture supernatant treatments markedly increased the p38 MAPKα levels (0.77-and 2.83-fold, respectively) (Fig. 4C). These findings suggest that p38 MAPKα is downstream of the PKAα signaling. Next, we evaluated the downstream PKAα and p38 MAPKα thermogenic markers under siRNA knockout conditions. We observed that the Ucp1, Pparγ, and Prdm16 mRNA expressions were markedly induced in siPKAα and sip38 MAPKα-knockdown cells following the DS0908 and DS0950 culture supernatant cotreatment (Fig. 4C). A similar expression pattern could also be observed at the thermogenic protein level (Figs. 4D and S3C). Overall, these data suggest that DS0908 and DS0950 promote thermogenesis via PKA/p38 MAPK signaling.

Discussion
Obesity is associated with several chronic diseases, including cardiovascular disease, non-alcoholic fatty liver disease, diabetes, cancer, and severe COVID-19 [34,35]. It begins with lipid content increase in white adipocytes, causing lipotoxicity and severe metabolic dysfunctions [16]. Therefore, the discovery of clinically significant antiobesity therapeutics that reduce fat accumulation in white adipocytes has gained popularity over the past decades. Probiotics are dietary supplements used against several metabolic diseases [36]. In this study, we demonstrated the potential of two probiotic strains, B. bifidum DS0908 and B. longum DS0950, to reduce adiposity by inducing thermogenesis and inhibiting lipid accumulation both in vitro and in vivo.
At the onset of obesity, high lipid amounts accumulate in the white adipocytes related to fatty acid synthase, sterol regulatory binding protein 1c (SREBP1c), and acetyl-CoA carboxylase activity [8,37,38]. Upon lipid accumulation, white adipocytes expand both in size and number. Lipid-laden white adipocytes secrete several adipokines, such as adiponectin, resistin, and leptin. Overexpression of these adipokines reportedly causes insulin resistance and glucose metabolism disruption [39,40]. High-fat content increases the TG, AST/GOT, ALT/GPT, CHO, and LDL levels, all of which are indicators of fatty liver disease [41]. Furthermore, an increased amount of mature white adipocytes increases body and organ weight and might affect food intake [8,42,43]. Multiple studies have reported that both culture supernatants and pellets of B. infantis reduce lipid accumulation in fat deposits by inhibiting adipo-and lipogenesis [7,8,11,44]. The reduced fat accumulation level improves the plasma lipid profile by reducing the TG, AST/GOT, ALT/GPT, CHO and LDL levels and increasing those of beneficial HDL [7,8,11]. We also found that HFD feeding increased obesity-related marker expression in mice. However, B. bifidum DS0908 and B. longum DS0950 supplementation reduced epididymal adipocyte size and body and organ weights without altering food intake. It also improved the plasma lipid profile, insulin sensitivity, and glucose utilization.
Other approaches for ameliorating obesity include non-shivering thermogenesis and lipolysis activation in mature white adipocytes. Several studies demonstrated that B. infantis and its culture supernatants (also known as postbiotics encompassing short-, medium-and long-chain fatty acids) can induce thermogenesis by promoting white adipocyte browning to beige and by improving brown adipocyte activity [8,9]. White-to-beige adipocyte conversion and adipogenic progenitor commitment to beige adipocytes are controlled by PPARγ, EBF2 and FGF21. EBF2 and FGF21 deletion blunt beige adipocyte formation, whereas their induction triggers thermogenesis in beige adipocytes [45,46]. PPARγ plays a key role in adipogenesis, supporting white adipocyte maturation. However, treatment of white adipocytes with PPARγ agonists and adipogenic progenitors reportedly leads to beige and brown adipocyte formation [20,21]. Both beige and brown adipocytes are characterized by high numbers of mitochondria and multi-locular lipid droplets. Mitochondria are considered the most important thermogenic process-related organelles. Mitochondria use electrons produced in free fatty acid lipid β-oxidation. While generating free fatty acids, lipolysis also produces small multi-locular lipids in adipocytes that are further processed by the mitochondria during thermogenesis [19,29]. Free fatty acid-driven oxidized electrons are carried through the mitochondrial ETC complexes and complemented by UCP1 to produce cellular ATP [29]. Active thermogenesis increases oxygen consumption and mitochondrial OXPHOS proteins [19]. In our study, B. bifidum DS0908 and B. longum DS0950 increased mitochondrial UCP1 and OXPHOS protein expressions. In addition, mitochondrial biogenesis increases mitochondrial content, which is known to contribute to thermogenesis. PGC1α reportedly improves mitochondrial biogenesis and oxidative phosphorylation, induced upon B. bifidum DS0908 and B. longum DS0950 supplementation [27,28]. PRDM16 reportedly complements beige and brown adipocyte activity both in mice and humans [24]. The Bifidobacterium strains considered in the current study increased the PRDM16 level.
Several studies described how an increase in beige and brown adipocyte marker expression reduces the levels of white adipocyte marker expression. We also observed the same expression patterns following B. bifidum DS0908 and B. longum DS0950 supplementation [8,19]. The increased expression of beige and brown adipocyte markers implies thermogenic improvement which alleviates obesity. Several signaling pathways tightly regulate the induction of these beige and brown adipocyte signatures. During the browning process, therapeutic candidates promote signaling protein (e.g., AMPK, PKA, p38 MAPK and CREB) phosphorylation, further inducing downstream thermogenic (common beige and brown) protein (i.e., PPARγ, PRDM16, PGC1α and UCP1) expressions [8,19,21,22]. Previous studies demonstrated that several probiotics, including B. infantis, can inhibit adiposity via AMPK and PKA/p38 MAPK signaling activation [7,8,44]. In addition, culture supernatants (postbiotics) produced by B. longum positively regulated thermogenesis via PKA signaling activation [8]. Isolated fatty acids (short-, medium-and long-chain fatty acids; postbiotics) from beneficial microbes (probiotics) positively affected thermogenic induction via GPR signaling induction. They reportedly alleviate obesity by inducing sustainable thermogenesis via GPR activation, such as GPR40, GPR43, GPR45 and GPR120 [10,13,47,48]. Interestingly, fatty acids can penetrate the blood-brain barrier and modulate insulin and leptin receptor expression in the hypothalamus via GPR signaling, possibly improving sustainable energy metabolism [10,13,47,48]. It is noteworthy that fatty acids activate cell surface GPR expression, further modulating the underlying signaling proteins (e.g., PKA, P38 MAPK and AMPK) [49][50][51]. In our study, culture supernatants of B. bifidum DS0908 and B. longum DS0950 activated PKA/p38 MAPK signaling in C3H10T1/2 MSCs during the promotion of thermogenesis. It is worth mentioning that multiple studies have investigated crude culture supernatants of probiotics as viable components to understand their role in alleviating obesity [7,8,44]. Although our study provides evidence of the thermogenic effect of B. bifidum DS0908 and B. longum DS0950 pellets and culture supernatants both in vitro and in vivo, these findings could be firmly bolstered by identifying key metabolites and investigating their anti-obesity effects via browning activation.
In summary, our study provides in vitro and in vivo evidence that B. bifidum DS0908 and B. longum DS0950 pellets and culture supernatants ameliorate obesity by activating the thermogenic program. In vivo study revealed that they improved the plasma lipid profile, insulin sensitivity, and glucose metabolism without altering food intake, suggesting that B. bifidum DS0908 and B. longum DS0950 and their culture supernatants might mitigate the clinical onset of obesity.